A safety arrangement in a motor vehicle includes a sensor (10) and a component (17) of the suspension of the vehicle of adjustable length between a front wheel (16) and a fixed part (14) of the vehicle. The component of adjustable length (17) is associated with a chamber (20) to be filled with fluid, there being a fluid outlet (26) which includes a pilot operated diaphragm valve (36).
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11. A safety arrangement for a motor vehicle having a suspension, the safety arrangement comprising:
a crash sensor configured to sense a potential accident situation involving the vehicle and to generate a signal;
a component of the suspension of the vehicle of adjustable length, located between at least each front wheel of the vehicle and a fixed part of the vehicle structure;
the component of adjustable length comprising a chamber filled with a fluid and having a fluid outlet provided with a valve arrangement, said valve arrangement being actuable in response to said signal to permit fluid to escape from the chamber, thereby reducing the overall length of the chamber to lower at least the front part of the vehicle, relative to the ground, in response to the sensing of a potential accident situation;
wherein said valve arrangement comprises a valve seat and a valve member, the valve member being moveable between a first position in which the valve member seals against the valve seat to prevent the flow of fluid between the valve member and the valve seat from within the chamber, and a second position in which the valve member is spaced from the valve seat to permit the flow of fluid between the valve member and the valve seat from within the chamber, the valve member initially being urged towards said first position by a pilot fluid supply at a pressure substantially equal to or greater than the pressure of the fluid within the chamber, there being provided an actuating arrangement to reduce the pressure of said pilot fluid supply below the pressure of the fluid within the chamber so as to move the valve member towards said second position; and
wherein said valve member comprises a membrane which is monostable and configured to return to said first position after actuation of the valve arrangement, when the fluid pressure within the chamber reduces to a predetermined level.
1. A safety arrangement for a motor vehicle having a suspension, the safety arrangement comprising:
a crash sensor configured to sense a potential accident situation involving the vehicle and to generate a signal;
a component of the suspension of the vehicle of adjustable length, located between at least each front wheel of the vehicle and a fixed part of the vehicle structure;
the component of adjustable length comprising a chamber filled with a fluid and having a fluid outlet provided with a valve arrangement, said valve arrangement being actuable in response to said signal to permit fluid to escape from the chamber, thereby reducing the overall length of the chamber to lower at least the front part of the vehicle, relative to the ground, in response to the sensing of a potential accident situation;
wherein said valve arrangement comprises a valve seat and a valve member, the valve member being moveable between a first position in which the valve member seals against the valve seat to prevent the flow of fluid between the valve member and the valve seat from within the chamber, and a second position in which the valve member is spaced from the valve seat to permit the flow of fluid between the valve member and the valve seat from within the chamber, the valve member initially being urged towards said first position by a pilot fluid supply at a pressure substantially equal to or greater than the pressure of the fluid within the chamber, there being provided an actuating arrangement to reduce the pressure of said pilot fluid supply below the pressure of the fluid within the chamber so as to move the valve member towards said second position; and
wherein said valve member comprises a membrane fixed around its periphery and moveable between a substantially convex configuration and a substantially concave configuration, one side of the membrane being in fluid communication with the pilot fluid supply and the opposite side of the membrane sealing against the valve seat when the membrane adopts said first position.
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1. Field of the Invention
THE PRESENT INVENTION relates to a safety arrangement for a motor vehicle, and more particularly, relates to a safety arrangement for a motor vehicle in the form of a light truck, pick-up truck, van or sports utility vehicle.
2. Description of the Related Art
Many vehicles, in the form of motor cars for private use, are provided with front and rear bumpers (also known as fenders), and may also be provided with side bumpers (or fenders). Typically, the bumpers on a motor vehicle are located at such a height above the road that the bumpers on the vehicle will engage the bumpers on another vehicle if the two vehicles are involved in an impact. Typically, the bumpers are located substantially in alignment with the floor-pan of the vehicle, if the vehicle is of monocoque construction, or are located substantially in alignment with the chassis of the vehicle, if the vehicle has a discrete chassis.
The bumpers are thus positioned to receive the energy that is applied to a vehicle in an impact situation and to transfer the energy to the parts of the vehicle structure that have been designed to absorb the energy.
There are nowadays an increasing number of vehicles in use on public roads, which may be described as “high” vehicles, in which the vehicle is provided with a substantial ground clearance, with the consequence that the bumpers provided on such a vehicle are located at a significantly higher level above the road surface than the bumpers on a more conventional “low” vehicle. Examples of such “high” vehicles may include light trucks, pick-up trucks, vans and sports utility vehicles.
When a “high” vehicle of the type described above is involved in impact with a conventional motor car, the bumper on the high vehicle is located substantially above the bumper on the conventional vehicle, and thus, in a frontal impact, the bumpers will not engage one another.
If a high vehicle 1 is involved in a side impact with a conventional vehicle 2, as shown in
It is to be understood, of course, that if a conventional vehicle is involved with a side impact with another conventional vehicle, the front bumper on the first conventional vehicle will be substantially at the level of the floor-pan 5 of the second vehicle.
The present invention seeks to provide a safety arrangement for a motor vehicle which will reduce or obviate the above-mentioned disadvantages of a “high” vehicle of the type described above.
According to the present invention, there is provided a safety arrangement for a motor vehicle, the safety arrangement comprising : a crash sensor configured to sense a potential accident situation involving the vehicle and to generate a signal; and a component of the suspension of the vehicle of adjustable length, located between at least each front wheel of the vehicle and a fixed part of the vehicle structure ;the component of adjustable length comprising a chamber filled with a fluid and having a fluid outlet provided with a valve arrangement, said valve arrangement being actuable in response to said signal to permit fluid to escape from the chamber, thereby reducing the overall length of the chamber to lower at least the front part of the vehicle, relative to the ground, in response to the sensing of a potential accident situation; wherein said valve arrangement comprises a valve seat and a valve member, the valve member being moveable between a first position in which the valve member seals against the valve seat to prevent the flow of fluid therebetween from within the chamber, and a second position in which the valve member is spaced from the valve seat to permit the flow of fluid therebetween from within the chamber, the valve member initially being urged towards said first position by a pilot fluid supply at a pressure substantially equal to or greater than the pressure of the fluid within the chamber, there being provided an actuating arrangement to reduce the pressure of said pilot fluid supply below the pressure of the fluid within the chamber so as to move the valve member towards said second position.
Preferably, said valve member comprises a membrane fixed around its periphery and moveable between a substantially convex configuration and a substantially concave configuration, one side of the membrane being in fluid communication with the pilot fluid supply and the opposite side of the membrane sealing against the valve seat when the membrane adopts said first position.
Advantageously, the membrane is monostable and configured to return to said first position after actuation of the valve arrangement, when the fluid pressure within the chamber reduces to a predetermined level.
Conveniently, the valve arrangement is provided in a side wall of said chamber.
Preferably, said actuating arrangement comprises a second valve arrangement actuable to vent said pilot fluid supply to atmosphere in response to said signal.
Advantageously, said second valve arrangement is actuable by a solenoid.
Conveniently, a suspension unit is provided between the axle or bearing of each front wheel of the vehicle and a fixed part of the vehicle structure, each suspension unit incorporating a said component of adjustable length.
Preferably, the chamber comprises a deformable inflatable element located between two suspension elements, the suspension elements being moveable telescopically relative to each other, but being distanced by the inflatable element, one said suspension element being connected to the fixed part of the vehicle structure and the other suspension element being connected to the axle or bearing of the wheel of the vehicle.
Advantageously, the inflatable element is filled with gas.
Conveniently, an inflator arrangement is provided to inflate the inflatable element when gas has been permitted to escape therefrom by the valve arrangement.
Preferably, the inflator arrangement comprises a compressor configured to supply compressed to the inflatable element and also to the valve member, so as to maintain said pilot fluid supply at the same pressure as the fluid within the inflatable element.
So that the invention may be more readily understood, and so that further features thereof may be appreciated, an embodiment of the invention will now be described, by way of example, with reference to the accompanying drawings in which:
At this stage, it is to be understood that the safety arrangement in accordance. with the present invention includes a sensor arrangement configured to sense a potential accident situation, and also incorporates an adjustment mechanism which adjusts the effective length of a component of the vehicle's suspension so that at least the front part of the vehicle is lowered relative to the ground. The front part of the vehicle will be lowered in a short period of time of the order of 200 ms (0.2 s) and the height of the bumper of the vehicle above the ground may be lowered by at least 100 mm, and preferably by 150–250 mm.
Thus, as shown in
The illustrated arrangement incorporates a suspension unit 13 which is connected between a fixed part 14 of the vehicle structure, and an axle 15 on which one of the front wheels 16 of the motor vehicle is mounted. Two identical suspension units of this type will be provided—one on each side of the vehicle—for each respective front wheel.
The suspension unit 13 takes the form of a generally conventional shock-absorber and includes an upper suspension element 17 comprising a generally cylindrical chamber, the upper part of the chamber being connected to the fixed part 14 of the vehicle structure, and a lower suspension element 18 which is connected (at 19) to the axle 15. The lower suspension element 18 takes the form of a piston which is telescopically received within the upper suspension element 17 in a manner known per se. However, whereas conventional motor vehicle shock-absorbers are generally provided with a helical coil spring therearound, in order to urge the two elements of the shock absorber apart, the safety arrangement of the present invention replaces the coil spring with a gas-filled chamber 20.
The gas-filled chamber 20 comprises an upper chamber element 21 having a substantially central aperture 22 to engage sealingly the outermost surface of the upper suspension element 17. The chamber 20 also comprises a lower chamber element 23 which is provided with a substantially central aperture 24 to engage sealingly the lower suspension element 18, at a position spaced below the lowermost end of the upper suspension element 17. The upper element 21 is fast with the upper suspension element 17 and the lower chamber element 23 is fast with the lower suspension element 18. Interconnecting the upper and lower chamber elements 21, 23, is a resiliently deformable sleeve 25 which is sealingly engaged at its uppermost end around the outer periphery of the upper chamber element 21, and is sealingly engaged at its lowermost end around the outer periphery of the lower chamber element 23. As clearly illustrated in
A main valve arrangement 26 is provided to seal an aperture formed in the side wall 27 of the sleeve 25. The main valve arrangement 26 comprises a pair of generally annular flanges 28, 29 which are configured to clampingly or otherwise sealingly engage the side wall 27 therebetween, around the periphery of an aperture 30. The outermost flange 28 is provided with a generally frustoconical inwardly-directed duct portion 31 whose innermost extent defines a generally annular valve seat 32 spaced slightly inwardly from the side wall 27 of the sleeve 25.
A valve housing 33 extends rearwardly from the innermost flange 29 around the valve seat 32 so as to define a valve chamber 34 therein. A number of gas-flow apertures 35 are provided through the side wall of the valve housing 33 at positions substantially adjacent the valve seat 32.
A moveable valve member in the form of a resilient membrane 36 is provided within the valve chamber 34, the membrane 36 being sealingly fixed around its periphery to the inner side wall of the valve chamber 34. The membrane 36 is configured so as to be moveable between the substantially. concave position illustrated in bold lines in
The valve housing 33 is provided with a small inlet/outlet aperture 37 in the rear wall of the housing 33, on the opposite side of the membrane to the valve seat 32. A flexible pilot tube 38 is connected to the inlet/outlet aperture 37. The flexible pilot tube 38 extends upwardly, within the gas-filled chamber 20 and extends through an aperture formed in the upper chamber element 21.
Also extending through the upper chamber element 21 is a gas feed tube 39 which extends from the internal volume of the chamber 20 to a second valve arrangement 40 for selective fluid connection to the pilot tube 38, an outlet vent 41 and a gas supply tube 42, the gas supply tube 42 being coupled to a gas supply unit 43 which preferably comprises an air compressor.
In the initial configuration illustrated in
With particular reference to
Returning now to consider the safety-arrangement as a whole, with reference to
It will therefore be appreciated that, when the flow path between the membrane 36 and the valve seat 32 is opened, gas from within the gas-filled chamber 20 is forced out through the aperture 30, thereby reducing the volume of gas within the chamber 20. Due to the weight of the vehicle pressing downwardly, the initial length L1 defined between the upper chamber element 21 and the lower chamber element 23 is reduced to a lesser length L2 as shown in
As can be seen from
Referring to
It is to be appreciated that once the valve arrangement 26 has been actuated to allow gas to escape from the gas-filled chamber 20, it will be necessary to replace that gas before the said arrangement is ready for re-use, allowing the vehicle to be driven safely. Thus, the actuating arrangement 12 can be operated to actuate the second valve arrangement 40 so that the outlet vent 41 is closed, and so that both the pilot tube 38 and the gas-feed tube 39 are fluidly connected to the gas-supply tube 42. Thereafter, the fluid supply unit (most preferably a compressor) 43 can be actuated to supply gas (most preferably air) to both the interior volume of the gas-filled chamber 20, and to the valve chamber 34.
It is to be appreciated that in the event that the valve membrane 36 is monostable as described above, then when a sufficient volume of gas has been released from the interior volume of the gas-filled chamber 20, the membrane 36 will automatically flip back to its concave configuration illustrated in bold lines in
The gas supply 43 continues to supply gas to the interior volume of the gas-filled chamber 20 until such time as the pressure of gas within the chamber 20 returns to its initial value, thereby returning the length between the upper and lower chamber elements 21, 22 to L1, thereby raising the front end of the vehicle back to its original ride height.
Whilst the invention has been described with reference to certain preferred embodiments, it is to be appreciated that many modifications may be made without departing from the scope of the invention. Whilst reference has been made to the front part of the vehicle being lowered in response to a potential accident situation being sensed, it is possible that the entire vehicle may be lowered. Also, whilst reference has been made to the use of gas (most preferably air) to fill the chamber 20 and operate the main valve arrangement 26, other arrangements could use other fluids, including liquid.
In the present specification “comprises” means “includes or consists of” and “comprising” means “including or consisting of”.
The features disclosed in the foregoing description, or the following claims, or the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for attaining the disclosed result, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.
Knight-Newbury, Heath, Macari, John
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Aug 05 2003 | Autoliv Development AB | (assignment on the face of the patent) | / | |||
Aug 07 2003 | KNIGHT-NEWBURY, HEATH | Autoliv Development AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 014729 | /0540 | |
Aug 07 2003 | MACARL, JOHN | Autoliv Development AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 014729 | /0540 |
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